CN1325149C - Alumina-doped mixed conductive compact oxygen-permeable membrane material - Google Patents

Alumina-doped mixed conductive compact oxygen-permeable membrane material Download PDF

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CN1325149C
CN1325149C CNB2005100387208A CN200510038720A CN1325149C CN 1325149 C CN1325149 C CN 1325149C CN B2005100387208 A CNB2005100387208 A CN B2005100387208A CN 200510038720 A CN200510038720 A CN 200510038720A CN 1325149 C CN1325149 C CN 1325149C
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oxygen
membrane material
alumina
permeable membrane
reaction
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CN1698939A (en
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徐南平
金万勤
吴振涛
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Nanjing Tech University
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Nanjing Tech University
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Abstract

The invention relates to a mixing for oxygen permeation and membrane reaction processesConductive compact oxygen permeable membrane material represented by the general formula C1-xC’xD1-yD’yO3-δThe composition of perovskite crystal type composite oxide and alumina, wherein delta is the oxygen lattice defect number, C, C 'is any one element of Ld, Sm, Nd, Pr, Ba, Ca, Sr, Na and La, D, D' is any one element of Mn, Cr, Fe, Co, Ni and Cu, x is more than or equal to 0 and less than or equal to 1, y is more than or equal to 0 and less than or equal to 1, and the content of alumina is 1-20% (by weight). It has good stability under high-temperature oxygen-deficient atmosphere, and is suitable for working for a long time under the condition of membrane reaction.

Description

Alumina doped mixed conductive compact oxygen permeable membrane material
Technical field
The present invention relates to a kind of alumina doped mixed conductive compact oxygen permeable membrane material.
Background technology
Disclose a kind of mixed conductor compact oxygen flow inorganic material film in the United States Patent (USP) (U.S.Pat.No.5,160,713, Nov.3,1992), this membrane material is that a kind of general formula is C 1-xC ' xD 1-yD ' yO 3-δPerovskite composite oxide, wherein δ is an oxygen lattice defect number, and C, C ' are any one element among Ld, Sm, Nd, Pr, Ba, Ca, Sr, Na, the La, and D, D ' are any one element among Mn, Cr, Fe, Co, Ni, the Cu, 0≤x≤1,0≤y≤1.This material has ion, electronics mixed conducting ability, can not only be under middle high temperature the selectivity oxygen flow, also have catalytic activity, thereby show very tempting application prospect at aspects such as pure oxygen preparation, fuel cell and chemical reactors.In recent years, adopt contained mixed conducting compact oxygen permeable membrane material to carry out partial oxidation reaction of methane and become research focus (Bouwmeester, 2003) in the methyl hydride catalyzed conversion field.Replace traditional separating air and making oxygen with mixed conductor membrane, reduce running cost more than 20% than traditional handicraft process, can control reaction process simultaneously, prevent temperature runaway (the Wilhelm et al. out of control that exothermic reaction causes, 2001), improved the security of operation.
Yet, contained mixed conducting compact oxygen permeable membrane material is used for oxygen flow and partial oxidation reaction of methane process aspect also exists the cost of film too high at present, therefore problems such as the structure of membrane material and chemical stability be high inadequately under oxygen flux and the reducing atmosphere still fail to obtain industrial applications.
Summary of the invention
The purpose of this invention is to provide a kind of aluminium mixed conductive compact oxygen permeable membrane material that contains, it not only has high oxonium ion and electronic conduction ability, and under high temperature anoxic atmosphere and reducibility gas atmosphere, still have good chemistry and structural stability, be suitable for long period of operation.
Mixed conductive compact oxygen permeable membrane material of the present invention is that general formula is C 1-xC ' xD 1-yD ' yO 3-δPerovskite crystal formation composite oxides and the composition of aluminium oxide, wherein δ is an oxygen lattice defect number, C, C ' are any one element among Ld, Sm, Nd, Pr, Ba, Ca, Sr, Na, the La, D, D ' are any one element among Mn, Cr, Fe, Co, Ni, the Cu, 0≤x≤1,0≤y≤1, wherein the content of aluminium oxide is 1~20% (weight percentage, as follows).
Membrane material of the present invention can adopt the conventional method preparation of solid reaction process, sol-gel process or organic acid complexometry.
Solid reaction process is after the oxide of each metallic element that this material is required (comprise aluminium element, down with) or carbonate, nitrate mix in proportion, and takes out after at high temperature reacting a period of time, grinds, sieves certain particle size and promptly get membrane material.
Sol-gel process is that the hydrolyzable predecessor with required each metallic element of this material is prepared into stable, transparent colloidal sol, and drying promptly gets membrane material after the heat treatment.
The organic acid complexometry claims " liquid hybrid technology " again, it is in the organic acid that the cationic salt of the required element of this material or oxide are dissolved in function groups, is made into the solution of finite concentration and pH, decomposes through elevated temperature heat, heat treatment, the powder that obtains certain particle size after the grinding promptly gets membrane material.
Above-mentioned membrane material can pass through conventional forming technique system films such as isostatic pressing method, wire-cut process.According to the difference of film composition, rise to 1000-1300 ℃ with the heating rate of 2 ℃/min, be incubated after 3-6 hour speed cooling back and take out with 2 ℃/min, promptly get film.
Among the present invention, the aluminium oxide of doping has improved the mechanical strength of former perovskite crystal formation material.Because this chemical property under hot conditions of aluminium oxide is very stable, thereby a spot of doping not only improved the microstructure of original perovskite oxide, and can improve the stable type of material under high temperature, anoxia condition.Material of the present invention not only has high oxygen transmission rate under the film reaction condition, also have good chemistry and structural stability under high temperature anoxic atmosphere, is applicable to methane portion oxidation, CO 2The industrial applications in film reaction such as thermal decomposition and fuel cell field.Al in addition 2O 3Adding can relatively effectively reduce the cost of material.
Description of drawings
Fig. 1 is existing perovskite material SrCo 0.8Fe 0.2O 3-δAnd Al 2O 3Doping is the material SrCo of the present invention of 1-10% 0.8Fe 0.2O 3-Al 2O 3The X-ray diffraction curve map of 950 ℃ of roastings after 5 hours under air atmosphere.
Fig. 2 is existing perovskite material SrCo 0.8Fe 0.2O 3-δWith Al 2O 3Doping is the material SrCo of the present invention of 1-10% 0.8Fe 0.2O 3-Al 2O 3Oxygen transmission rate is (partial pressure of oxygen gradient 0.21/1 * 10 relatively -3Atm).
Fig. 3 is Al 2O 3Doping is the material SrCo of the present invention of 1-10wt% 0.8Fe 0.2O 3-Al 2O 3Prepared diaphragm is the X-ray diffraction curve map before and after the oxygen flow experiment.
Fig. 4 is Al 2O 3Doping is 3% material SrCo of the present invention 0.8Fe 0.2O 3-Al 2O 3Be equipped with stability data in the synthesis gas process at partial oxidation of methane.
The specific embodiment
Below in conjunction with the description of drawings embodiments of the invention.
Embodiment 1
With existing perovskite material SrCo 0.8Fe 0.2O 3-δAnd Al 2O 3Doping be 1,3,5 and 10% material of the present invention respectively under 950 ℃ of air atmospheres roasting advance the X-ray diffraction test after 5 hours, the results are shown in Figure 1.
As can be seen from Figure 1, Al 2O 3Doping the dephasign peak do not occur at the material of 1-5 weight %, illustrates to have formed complete perovskite structure; Al 2O 3Doping 10% occurs such as Al 2O 3, CoAl 2O 4And SrFe 7Al 5O 19Deng dephasign.With SrCo 0.8Fe 0.2O 3-δMaterial is compared, and mixes 10%Al 2O 3Near the diffraction maximum of material 32 ° certain skew has appearred, variation has taken place in the microstructure of illustrative material.
Embodiment 2
With Al 2O 3Doping be 1,3 and 10% material of the present invention simple oxygen flow condition under, be 0.21/1 * 10 with the partial pressure of oxygen gradient respectively -3Atm carries out the oxygen transmission rate test, and it the results are shown in Figure 2.
Fig. 2 as can be seen, oxygen permeating amount reduces along with decrease of temperature, and along with Al 2O 3The increase of doping and descending.
Embodiment 3
To Al 2O 3Doping is that 1,3,5 and 10% material of the present invention carries out the X-ray diffraction test before and after the oxygen flow, result such as Fig. 3 respectively.
Fig. 3 result as can be seen, 1-5%Al 2O 3The SrCo that mixes 0.8Fe 0.2O 3-δStructure almost is consistent before and after the oxygen flow experiment, and 10%Al 2O 3The SrCo that mixes 0.8Fe 0.2O 3-δMaterial trickle variation has taken place, illustrate that in the membrane catalytic reaction process, latter material's changes of microstructure is than Al 2O 3The material that doping is lower can be more obvious.So Al in the material of the present invention 2O 3Doping is no more than 20%, Al 2O 3The optimized scope of doped account at 1-10%, the material in this doping scope is more stable.
Embodiment 4
The application of material membrane of the present invention in the membrane catalytic reactor that is equipped with synthesis gas (POM) at partial oxidation of methane
With Al 2O 3Doping be that 3% material membrane of the present invention is applied to NiO/Al 2O 3For the partial oxidation of methane of catalyst is equipped with in the membrane catalytic reaction of synthesis gas (POM), reaction equation is as follows: CH 4+ 1/2O 2=2H 2+ CO.
Film one side feeds CH 4And He, flow is respectively 2.9ml/min and 17.9ml/min, and film opposite side bubbling air, flow are 100ml/min, stable reaction is moved nearly 500 hours, and reaction product gas carries out on-line analysis by two gas-chromatographies (Model Shimadzu GC-7A and Model SP-6800).Analysis result is seen Fig. 5.Among the figure: S COThe expression carbon monoxide selective; H 2: CO represents the mol ratio of hydrogen and carbon monoxide in the product; X CH4The expression methane conversion; J O2Al in the expression POM reaction 2O 3The oxygen permeating amount of 3% material of the present invention mixes.
As seen from Figure 4, S COMaintain 100%, illustrate in the raw material that the methane that participates in reaction all is converted into carbon monoxide, and do not generate other products such as carbon dioxide; H 2: CO maintains about 2 substantially, illustrates that the equation that reacts according to the POM reaction carries out; X CH4On average about 45%, can further improve by changing operating condition.JO 2Explanation is in 500 hours course of reaction only, and the oxygen flux ratio more stably maintains 2ml/ (cm 2Min) about, the oxygen flow ability is stable.
Al 2O 33% material of the present invention that mixes can show Al nearly 500 hours of stable operation in the POM reaction 2O 3Mix and obviously improved heat endurance and the chemical stability of material under high temperature, reducing atmosphere condition.Original material bibliographical information is under the POM reaction condition, and beginning soon in reaction, film promptly breaks.
Material of the present invention is in the POM reaction, and oxygen permeability is improved significantly, and reacts the higher oxygen permeation flux that do not break yet and possessed in 500 hours, CO selectivity and H in the product 2Remain near the theoretical numerical value with the ratio of CO is all stable.Can effectively satisfy and utilize membrane catalytic reactor to realize that partial oxidation of methane is equipped with in the synthesis gas process route requirement for the membrane material oxygen permeability.
Embodiment 5
Be doped with Al 2O 3The solid reaction process preparation and the film forming example of material of the present invention.
With certain stoichiometric SrCO 3, Co 2O 3, Fe 2O 3And Al 2O 3Mixed ball milling 24 hours, subsequently 1223 K calcination 4 hours.With the membrane material after the roasting grind material powder of the present invention.Powder makes the film base substrate under the uniaxial tension of 300MPa; Obtained film base is placed the Si-Mo rod stove, rise to 1473 K, be incubated 5 hours, reduce to room temperature with same speed again, make laminar film.Can make tubular membrane with wire-cut process or isostatic pressing method.

Claims (2)

1. an alumina doped mixed conductive compact oxygen permeable membrane material is characterized in that this material is C by general formula 1-xC ' xD 1-yD ' yO 3-δPerovskite crystal formation composite oxides and the composition of aluminium oxide, wherein δ is an oxygen lattice defect number, C, C ' are any one element among Ld, Sm, Nd, Pr, Ba, Ca, Sr, Na, the La, D, D ' are any one element among Mn, Cr, Fe, Co, Ni, the Cu, 0≤x≤1,0≤y≤1, wherein the weight content of aluminium oxide is 1~20%.
2. according to the alumina doped mixed conductive compact oxygen permeable membrane material of claim 1, the content that it is characterized in that aluminium oxide is 1~10%.
CNB2005100387208A 2005-04-06 2005-04-06 Alumina-doped mixed conductive compact oxygen-permeable membrane material Active CN1325149C (en)

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* Cited by examiner, † Cited by third party
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CN101450861B (en) * 2007-12-06 2011-12-14 中国科学院大连化学物理研究所 Method for preparing unsymmetrical biphase composite oxygen permeable membrane
CN101274224B (en) * 2008-05-12 2010-12-01 南京工业大学 Highly stable molybdenum-based mixed conductor compact oxygen permeable membrane material and preparation method and application thereof
CN106431400A (en) * 2016-07-10 2017-02-22 上海大学 CO2 corrosion resistant biphase mixed-conducting oxygen permeable membrane material and preparation method thereof
CN107198973B (en) * 2017-06-12 2020-04-03 上海大学 Can increase CO2Preparation method of iron-based ceramic oxygen permeable membrane with oxygen permeation stability under atmosphere

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5160713A (en) * 1990-10-09 1992-11-03 The Standard Oil Company Process for separating oxygen from an oxygen-containing gas by using a bi-containing mixed metal oxide membrane
CN1203831A (en) * 1998-05-06 1999-01-06 南京化工大学 Mixed conductive compact oxygen permeable membrane material

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5160713A (en) * 1990-10-09 1992-11-03 The Standard Oil Company Process for separating oxygen from an oxygen-containing gas by using a bi-containing mixed metal oxide membrane
CN1203831A (en) * 1998-05-06 1999-01-06 南京化工大学 Mixed conductive compact oxygen permeable membrane material

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